The Narrow Pulse Approximation and Long Length Scale Determination in Xenon Gas Diffusion NMR Studies of Model Porous Media

Mair, R. W.; Sen, Parongama; Hürlimann, Martin D.; Patz, Samuel; Cory, David G.; Walsworth, Ronald L.

doi:10.1006/jmre.2002.2540

Cited by 75 publications

(86 citation statements)

References 31 publications

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“…Excellent agreement was found between S/V estimates from the Padé approximant and microscopy performed on monosized sphere packs [17,37]. To date, this non-specific approach has not been applied to the characterization of cancer cells.…”

Section: For All the Rest Of Timementioning

confidence: 81%

Time-Dependent Diffusion MRI in Cancer: Tissue Modeling and Applications

Reynaud

2017

Front. Phys.

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In diffusion weighted imaging (DWI), the apparent diffusion coefficient (ADC) has been recognized as a useful and sensitive surrogate for cell density, paving the way for non-invasive tumor staging, and characterization of treatment efficacy in cancer. However, microstructural parameters, such as cell size, density and/or compartmental diffusivities affect diffusion in various fashions, making of conventional DWI a sensitive but non-specific probe into changes happening at cellular level. Alternatively, tissue complexity can be probed and quantified using the time dependence of diffusion metrics, sometimes also referred to as temporal diffusion spectroscopy when only using oscillating diffusion gradients. Time-dependent diffusion (TDD) is emerging as a strong candidate for specific and non-invasive tumor characterization. Despite the lack of a general analytical solution for all diffusion times/frequencies, TDD can be probed in various regimes where systems simplify in order to extract relevant information about tissue microstructure. The fundamentals of TDD are first reviewed (a) in the short time regime, disentangling structural and diffusive tissue properties, and (b) near the tortuosity limit, assuming weakly heterogeneous media near infinitely long diffusion times. Focusing on cell bodies (as opposed to neuronal tracts), a simple but realistic model for intracellular diffusion can offer precious insight on diffusion inside biological systems, at all times. Based on this approach, the main three geometrical models implemented so far (IMPULSED, POMACE, VERDICT) are reviewed. Their suitability to quantify cell size, intra-and extracellular spaces (ICS and ECS) and diffusivities are assessed. The proper modeling of tissue membrane permeability-hardly a newcomer in the field, but lacking applications-and its impact on microstructural estimates are also considered. After discussing general issues with tissue modeling and microstructural parameter estimation (i.e., fitting), potential solutions are detailed. The in vivo applications of this new, non-invasive, specific approach in cancer are reviewed, ranging from the characterization of gliomas in rodent brains and observation of time-dependence in breast tissue lesions and prostate cancer, to the recent preclinical evaluation of new treatments efficacy. It is expected that clinical applications of TDD will strongly benefit the community in terms of non-invasive cancer screening.

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Section: For All the Rest Of Timementioning

confidence: 81%

Time-Dependent Diffusion MRI in Cancer: Tissue Modeling and Applications

Reynaud

2017

Front. Phys.

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“…In future work, we will test our technique in more challenging experimental situations, such as in more elaborate phantoms and in lung airspaces in vivo, having much higher surface-to-volume ratios and thus much shorter time-scale requirements. These studies will concentrate on experimental regimes in which other groups have observed the breakdown of other diffusion-weighted pulse sequences at atmospheric pressure [15,29]. Future efforts will also concentrate on adapting our basic strategy, which in its present form yields global diffusion measurements, to provide spatially resolved measurements by incorporating k-space readout into our pulse sequence.…”

Section: Discussionmentioning

confidence: 99%

“…The same strategy for eliminating the T 2 * dependence has been used elsewhere [29] and resembles the b = 0 reference measurement typically used in the single-bipolar method. It follows that the ratio of these two signal measurements is given by: (6) and a linear fit to ln[R(n)] vs. nb yields D. Note that the fraction A 1 /A 2 , which contains the effect of RF signal consumption between excitations, does not affect the calculation of D, and hence renders flip angle corrections unnecessary for our method.…”

Section: Data Sampling and Analysismentioning

confidence: 99%

Measurement of hyperpolarized gas diffusion at very short time scales

Carl

Miller

Mugler

et al. 2007

Journal of Magnetic Resonance

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We present a new pulse sequence for measuring very-short-time-scale restricted diffusion of hyperpolarized noble gases. The pulse sequence is based on concatenating a large number of bipolar diffusion-sensitizing gradients to increase the diffusion attenuation of the MR signal while maintaining a fundamentally short diffusion time. However, it differs in several respects from existing methods that use oscillating diffusion gradients for this purpose. First, a wait time is inserted between neighboring pairs of gradient pulses; second, consecutive pulse pairs may be applied along orthogonal axes; and finally, the diffusion-attenuated signal is not simply read out at the end of the gradient train but is periodically sampled during the wait times between neighboring pulse pairs. The first two features minimize systematic differences between the measured (apparent) diffusion coefficient and the actual time-dependent diffusivity, while the third feature optimizes the use of the available MR signal to improve the precision of the diffusivity measurement in the face of noise. The benefits of this technique are demonstrated using theoretical calculations, Monte-Carlo simulations of gas diffusion in simple geometries, and experimental phantom measurements in a glass sphere containing hyperpolarized 3 He gas. The advantages over the conventional single-bipolar approach were found to increase with decreasing diffusion time, and thus represent a significant step toward making accurate surface-to-volume measurements in the lung airspaces.

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“…[48], the T 1,Xe -time of 129 Xe in our pressure range is the combined effect of the density independent wall relaxation T 1,wall have to be optimized (Eq. (6)), the influence of the increased total gas pressure on the field gradient induced transverse relaxation time has to be reconsidered: In a gas mixture (GM) with N 2 as buffer gas, the resulting diffusion coefficients for 3 He and 129 Xe are given by [49] In Fig.9, the dependence of T 2 with vdW field…”

mentioning

confidence: 99%

Ultra-sensitive magnetometry based on free precession of nuclear spins

Gemmel¹,

Heil²,

Karpuk³

et al. 2010

Eur. Phys. J. D

123

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We discuss the design and performance of a very sensitive low-field magnetometer based on the detection of free spin precession of gaseous, nuclear polarized 3 He or 129 Xe samples with a SQUID as magnetic flux detector. The device will be employed to control fluctuating magnetic fields and gradients in a new experiment searching for a permanent electric dipole moment of the neutron as well as in a new type of 3 He/ 129 Xe clock comparison experiment which should be sensitive to a sidereal variation of the relative spin precession frequency. Characteristic spin precession times after one day. Even in that sensitivity range, the magnetometer performance is statistically limited, and noise sources inherent to the magnetometer are not limiting. The reason is that free precessing 3 He ( 129 Xe) nuclear spins are almost completely decoupled from the environment. That makes this type of magnetometer in particular attractive for precision field measurements where a long-term stability is required.

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The Narrow Pulse Approximation and Long Length Scale Determination in Xenon Gas Diffusion NMR Studies of Model Porous Media

Cited by 75 publications

References 31 publications

Time-Dependent Diffusion MRI in Cancer: Tissue Modeling and Applications

Time-Dependent Diffusion MRI in Cancer: Tissue Modeling and Applications

Measurement of hyperpolarized gas diffusion at very short time scales

Ultra-sensitive magnetometry based on free precession of nuclear spins

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